Index-based Most Similar Trajectory Search

The problem of trajectory similarity in moving object databases is a relatively new topic in the spatial and spatiotemporal database literature. Existing work focuses on the spatial notion of similarity ignoring the temporal dimension of trajectories and disregarding the presence of a general-purpose spatiotemporal index. In this work, we address the issue of spatiotemporal trajectory similarity search by defining a similarity metric, proposing an efficient approximation method to reduce its calculation cost, and developing novel metrics and heuristics to support k-most-similar-trajectory search in spatiotemporal databases exploiting on existing R-tree-like structures that are already found there to support more traditional queries. Our experimental study, based on real and synthetic datasets, verifies that the proposed similarity metric efficiently retrieves spatiotemporally similar trajectories in cases where related work fails, while at the same time the proposed algorithm is shown to be efficient and highly scalable.

[1]  Dimitrios Gunopulos,et al.  Discovering similar multidimensional trajectories , 2002, Proceedings 18th International Conference on Data Engineering.

[2]  Nirvana Meratnia,et al.  Spatiotemporal Compression Techniques for Moving Point Objects , 2004, EDBT.

[3]  Hanan Samet,et al.  Distance browsing in spatial databases , 1999, TODS.

[4]  Timos K. Sellis,et al.  Spatio-temporal indexing for large multimedia applications , 1996, Proceedings of the Third IEEE International Conference on Multimedia Computing and Systems.

[5]  Christos Faloutsos,et al.  FTW: fast similarity search under the time warping distance , 2005, PODS.

[6]  Yannis Theodoridis,et al.  Ten Benchmark Database Queries for Location-based Services , 2003, Comput. J..

[7]  Jimeng Sun,et al.  Analysis of predictive spatio-temporal queries , 2003, TODS.

[8]  Christos Faloutsos,et al.  Efficient Similarity Search In Sequence Databases , 1993, FODO.

[9]  Dieter Pfoser,et al.  Novel Approaches to the Indexing of Moving Object Trajectories , 2000, VLDB.

[10]  Jianwen Su,et al.  Shapes based trajectory queries for moving objects , 2005, GIS '05.

[11]  Ada Wai-Chee Fu,et al.  Efficient time series matching by wavelets , 1999, Proceedings 15th International Conference on Data Engineering (Cat. No.99CB36337).

[12]  Nikos Pelekis,et al.  Algorithms for Nearest Neighbor Search on Moving Object Trajectories , 2007, GeoInformatica.

[13]  Tetsuji Satoh,et al.  Shape-Based Similarity Query for Trajectory of Mobile Objects , 2003, Mobile Data Management.

[14]  Eamonn Keogh Exact Indexing of Dynamic Time Warping , 2002, VLDB.

[15]  Donald J. Berndt,et al.  Finding Patterns in Time Series: A Dynamic Programming Approach , 1996, Advances in Knowledge Discovery and Data Mining.

[16]  Lei Chen,et al.  Robust and fast similarity search for moving object trajectories , 2005, SIGMOD '05.

[17]  Dimitrios Gunopulos,et al.  Rotation invariant distance measures for trajectories , 2004, KDD.

[18]  Eamonn J. Keogh,et al.  LB_Keogh supports exact indexing of shapes under rotation invariance with arbitrary representations and distance measures , 2006, VLDB.

[19]  Raymond T. Ng,et al.  Indexing spatio-temporal trajectories with Chebyshev polynomials , 2004, SIGMOD '04.